Research Areas

Kawasaki disease (KD) is an acute febrile illness and systemic vasculitis of unknown etiology that predominantly affects young children, causes coronary artery abnormalities and aneurysms and could potentially result in long-term cardiovascular sequelae and even death. While intravenous immunoglobulin (IVIG) treatment lowers the risk of developing coronary artery aneurysms to 5%, up to 20% of KD patients are IVIG-resistant and are at greater risk for coronary artery aneurysms. Therefore, discovery of more effective treatments to prevent the cardiovascular complications of KD vasculitis is a high priority in pediatric and cardiovascular research. The Noval Rivas Laboratory uses the Lactobacillus casei cell wall extract (LCWE) mouse model of KD vasculitis, which closely reproduces the important histologic as well as pathologic features of the human disease, to further decipher the innate and adaptive immune responses involved in KD development. For more information, see Kawasaki disease: pathophysiology and insights from mouse models.

The intestinal microbiome is an integral part of our physiology. Intestinal dysbiosis influences the development of a number of immunological and non-immunological disorders, including cardiovascular diseases. The Noval Rivas Laboratory is investigating how the intestinal microbiome influences KD development and pathology. We recently discovered that intestinal permeability and dysregulated mucosal immune responses play a key role in the development of coronary arteritis and aneurysm formation in the LCWE murine model of KD vasculitis. For more information, see Intestinal permeability and IgA provoke immune vasculitis linked to cardiovascular inflammation.

The abrupt increase in food allergy incidence implicates environmental factors in disease pathogenesis and correlates with societal and lifestyle changes over the last decades. Allergy to innocuous food antigens reflects a breakdown in oral tolerance, which is enforced by food-allergen specific regulatory T cells (T_Regs). However, mechanisms involved in oral tolerance breakdown are still not completely understood. By using Il4raF709 transgenic mice, characterized by enhanced oral allergic sensitization and heightened Th2 immune responses, the Noval Rivas Lab has demonstrated that food allergy is associated with a defective induction of allergen-specific T_Regs. Moreover, T_Regs from both allergic mice and food allergic patients exhibit decreased suppressive activities due to a Th2-like pathogenic reprograming characterized by elevated GATA3 and IRF4 expression and increased IL-4 production. Food allergic Il4raF709 mice also exhibit a dysbiotic commensal microbiota and oral tolerance can be transferred by fecal transplantation of microbiota from non-allergic mice. We are currently pursuing studies in order to decipher further the host-microbiota interactions involved in food allergy development in the aim to identify fundamental immunological and microbial mechanisms involved in oral tolerance breakdown and food allergy pathogenesis. For more information, please see A microbiota signature associated with experimental food allergy promotes allergic sensitization and anaphylaxis and Regulatory T cell reprogramming toward a Th2-cell-like lineage impairs oral tolerance and promotes food allergy.